[0001] The present invention relates to a method of pretreating the surface of a medical
device intended for appliance of a biological coating, and for applying a biological
coating to the surface of such medical device, according to the preambles of claims
1 to 4.
[0002] A common problem in medical devices intended for blood contact is the biocompatibility
of the surface of such devices. Medical devices, such as artificial heart valves,
are often in permanent or at least long-lasting contact with human or animal blood.
By the way, this does not only apply to medical devices implanted or otherwise introduced
into the human or animal body, but also to medical devices used in extracorporeal
systems like a heart-lung machine.
[0003] If no special care is taken, the contact between the medical device and the blood
may result in so-called "clotting" (coagulation) at the surface of the medical device.
Such clots may render the medical device (e.g. a sensor) inoperable. Further, they
may reduce the free-space sectional area of a blood vessel, therefore reducing blood
flow. Even worse, a clot formed on the surface of the medical device may be detached
by the flowing blood and occlude a blood vessel (in particular, a capillary) thus
causing thrombosis.
[0004] The situation is even more critical in case of a catheter or an intravascular blood
gas sensor introduced in a blood vessel of relatively small diameter such as the radial
artery or the femoral artery. The catheter may be completely blocked by a clot, so
that the blood pressure cannot be measured or that no blood samples can be taken;
in case of an intravascular blood sensor, the active area may be blocked (i.e. no
fresh blood can reach the sensor).
[0005] The above considerations are of particular importance when long-term contact between
the medical device and the blood is intended. Even with optimum material selection
for the medical device, clotting cannot be reliably prevented.
[0006] A common approach to solve this problem, i.e. to prevent the formation of clots,
is to coat the medical devices with a biological coating (sometimes also referred
to as bioactive or antithrombogenic coating). Coatings suited for this purposes are
well-known in the art. For example, a heparin-based coating, such as described in
United States Patent U.S. 4,810,784, may be used. Other suitable biocompatible materials
are e.g. phosphorylcholine (EP-B-157 469) or polyester (U.S. 4,792,599). Hirudin may
be used as well. Further biological coating materials useful as anticoagulants are
known in the art.
[0007] A common problem when applying such biological coatings to a medical device is to
ensure reliable adhesion between the coating and the surface of the medical device,
i.e. reliable immobilization of the coating. It is understood that a bad contact would
lead to detachment of the coating, so that the medical device looses its antithrombogenic
properties. As the biological coating does not adhere to the surface of the medical
device by itself, additional measures have to be taken. Further, it has to be ensured
that the biological coating does not loose its bioactive properties during the immobilization
process.
[0008] A known solution to this problem is to coat the surface of the medical device with
a polymer and to apply the biological coating to the polymerized surface. For this
purpose, the pure (uncoated) medical device is put into a polymer bath, i.e. a solvent
containing dissolved polymer. When the medical device is removed, its surface carries
a thin film of solvent containing the polymer. The solvent then vaporizes, such that
the pure polymer resides on the surface of the medical device. Subsequently, the biological
coating is applied, e.g. by putting the medical device into an appropriate bath.
[0009] However, the immobilization of a biological coating fastened on the surface of a
medical device in this manner is not always reliable. The inventor in the present
case has particularly noted that parts of the biological coating detached in use from
an intervascular blood gas sensor. This has particularly happened when a medical device
is stored or deposited in a liquid for a longer time period (e.g. an intravsacular
sensor requiring a wet or liquid environment to keep its operability even when not
in use). Such detachment is an untolerable disadvantage of the known technique, partially
because of the danger for the patient as blood clots may attach to the uncoated portions
of the surface, and partially as such removal of the biological coating may affect
the measuring accuracy of the sensor when parts of it are coated and others are not.
[0010] It is therefore a major objective of the present invention to provide a method for
reliable attachment of a biological coating to the surface of a medical device.
[0011] According to one aspect of the invention, this object is solved by performing the
following steps:
1. The medical device is exposed to a chemical agent consisting of monomer molecules
chemically combined with functional groups, said chemical agent being present at least
in its gaseous state;
2. electromagnetic waves, in particular in the radio frequency range, are irradiated
into said chemical agent and/or onto the surface of said medical device until the
molecules of said chemical agent constitute a functional polymer on the surface of
the medical device, and
3. the biological coating is applied to the surface of the medical device.
[0012] The invention makes use of a basically well-known technique called "plasma polymerization".
According to this technique, the object to be coated with a polymer is put in a pressure-tight
chamber. Monomeres in gaseous form are then conducted into the chamber. A source of
electromagnetic radiation irradiates high-frequency waves into the chamber, thereby
creating a plasma (i.e. a gas containing free radicals). Even during spark discharge,
temperature in the chamber is only slightly increased.
[0013] The plasma thus created allows the monomeres to polymerize on the surface of the
object. The polymer forms a thin layer on the surface, just like a very thin hose
or tube.
[0014] In the light of the unsatisfying results obtained with the above described technique
of applying dissolved polymers to the surface of the medical device, the inventor
has investigated usual (e.g. thermal) polymerization techniques (thermolysis, photolysis,
use of radical starters); i.e. techniques wherein no polymer molecules are applied
to the surface, but monomeres instead, and polymerization is then effected. This could
be an attractive approach as the single polymer molecules are more effectively "muddling"
thus leading to increased consistency.
[0015] However, even these usual polymerization techniques did not produce a satisfying
result. Attempts have then been made with the above described plasma polymerization
technique, but also with limited success.
[0016] But then, the inventor has surprisingly found that the desired effect can be achieved
if not simple monomeres (as have been used in prior art techniques) are used, but
monomeres with an additional functional group instead. In fact, plasma polymerization
of monomeres with a functional group resulted in a coating which was able to keep
the biological coating very reliably in place. Studies have shown that the biological
coating does not detach from polymeres produced in this way, even in long-term use.
[0017] The present invention thus overcomes the disadvantages of the prior art. In particular,
medical devices coated with a first polymer coating according to the invention and
a second (biological) coating have proven to operate very accurate (i.e. their operation
is not impaired by the coating). This is e.g. important for medical sensors, since
the sensor reading should not be influenced by either coating. Still the biological
coating does adhere to the surface of the medical device over very long time periods,
so that thrombosis and other negative effects are avoided. This is particularly due
to the functional groups of the polymer which adhere chemically to the biological
coating. ("Functional polymer" as used herein means a polymer with functional groups.)
Further, the biological coating is able to resist considerable mechanical stress.
[0018] Although made when investigating the biological coating of an intravascular blood
gas sensor, and although the invention is particularly suited for such sensor, it
is understood that the inventive method may also be applied to a variety of other
medical devices intended for blood contact, such as artificial blood vessels, heart
valves, catheters and the like. Intravascular blood gas sensors as such are basically
known in the art, see e.g. EP-B-279 004, EP-B-336 984 and EP-A-336 985; the full content
of these publications is hereby incorporated into the disclosure of the present invention
by reference.
[0019] In the case of an intravascular blood gas sensor, the "plasma" coating generated
by the inventive method has further advantages. In particular, such sensor consists
of a variety of materials, e.g. the coating of the single sensors, the semipermeable
membranes covering their diffusion zones, a sheath etc., which are all in blood contact.
Therefore, if the biological coating would be directly applied to the sensor, it would
cover areas of different consistency and different physical properties; it could thus
happen that the biological coating does not behave in a uniform manner. E.g. its resistance
to the accumulation or adhesion of clots could be varying, dependent on the covered
material, or it could detach from certain areas only and remain on other areas (the
latter effect is particularly disadvantageous as a
limited detachment, e.g. restricted to several square micrometers, is difficult to detect,
but still dangerous for the patient). These problems and disadvantages are overcome
by the present invention, as it is now possible to provide a uniform and reliable
polymer coating, so that the biological coating adheres to a uniform material.
[0020] It is a further advantage of the inventive method that it can be implemented very
easily and in a cost-effective manner. This is because a basically known apparatus
can be used to effect plasma polymerization, so the only basic modification is the
use of monomeres with an additional functional group.
[0021] To apply the polymer coating, the medical device is put in a closed, preferably pressure-tight
chamber. The gaseous chemical agent consisting of monomer molecules chemically combined
with functional groups is then allowed to stream into said chamber through an appropriate
opening or valve, preferably from a container or the like filled with said chemical
agent. Next, a source of radiation energy is switched on. This source may be arranged
at a side wall of the chamber or in an annular arrangement around the chamber (which
preferably has a cylindrical cross section). Other suitable arrangements of the radiation
source may be used as well. Because of the high intensity of the radiation, an electrically
shielded chamber is preferred. In an advantageous embodiment, the emitted electromagnetic
waves are in the radio frequency spectrum; specifically, a frequency of 13.56 MHz
(MegaHertz) has been used. The electromagnetic waves are irradiated into the chamber,
and the spark discharge causes the gaseous chemical agent to form a "plasma", e.g.
a gas with free radicals. This allows the monomeres with their respective functional
groups to form a polymer which covers the surface of the medical device.
[0022] The biological coating may then be applied to the polymer-coated surface in basically
known manner. I.e. it is not necessary to apply the biological coating immediately
to the polymer coating in order to satisfy free bondings of the polymer. Instead,
the polymer-coated medical device may be removed from the chamber and then put into
a chemical bath in order to apply the biological coating. It is even not necessary
that the step of applying the biological coating is performed immediately after the
appliance of the polymer coating; instead, the biological coating may be applied weeks
later. The appliance of the polymer coating and the biological coating are chemically
"separate" steps. Therefore, the present invention does not only relate to the combination
of applying a polymer coating and a biological coating, but also to a method for pretreating
the surface of a medical device according to claim 1, i.e. it relates to the steps
necessary to apply a polymer coating, in preparation of the appliance of the biological
coating itself.
[0023] The process of plasma polymerization may be significantly improved by the use of
underpressure, i.e. a pressure below atmospheric pressure. This can be achieved by
a pressure-tight chamber which is approximately evacuated. Advantageously, the pressure
is reduced until it is in a range from 0.01 millibar to 10 millibar, and more specifically,
in a range from 0.1 millibar to 1 millibar. In one embodiment of the invention, a
pressure of 0.3 millibar (3·10⁻⁴ bar) has been applied to the chamber, for a duration
of around 20 minutes and with a RF (radiation frequency) power of 30 mW (milliwatts),
with excellent results.
[0024] As outlined above, the used chemical agent consists of monomeres incorporating functional
groups. The wording "monomer molecules chemically combined with functional groups"
used herein means that each (or at least the majority of) monomer molecules is combined
with or bound to at least one functional group. Monomeres as the basis for polymerization
as such are well-known in the art. A common basic structural formula for monomeres
is
wherein R
n denotes hydrogen atoms, halogen, halide or organic residues or radicals (see for
example Alfred Kemper/Rüdiger Fladt, Chemie, Stuttgart 1968, p. 290).
[0025] According to the present invention, the used monomeres are further chemically combined
with (bound to) functional groups. Such functional groups are at least partially kept
during the plasma coating process and result in a functional polymer which can covalently
bind to other molecules (this process will be described in detail below). In a general
sense, a functional group is a chemically active or reactive group (responsive to
substitution or rearrangement), and more specifically, a functional group can be defined
as a group which tends to amide formation, amine formation, acid formation, esterification,
etherification etc.
[0026] There are several functional groups which have been found advantageous. A preferred
group is e.g. the amino group, -NH₂. Each monomer molecule may be combined with one
or more amino groups. (It is understood that further groups, radicals etc. may also
be chemically bound to such a "functional monomer"). A typical useful chemical agent
consisting of a monomer and an amino group ("functional monomer") is allylamine, H₂C=CH-CH₂-NH₂.
The surface of the medical device polymerized with allylamine comprises free amino
groups, which in turn may bind to the molecules of the biological coating (see below).
Another chemical agent of this kind is 4-amino-1-butene, H₂C=CH-CH₂-CH₂-NH₂. It is
understood that other olefins with additional amino groups are advantageous as well
(in general: H₂C=CH-(CH₂)
n-NH₂, n=0,1,2,...).
[0027] Instead of using an olefin with appended amino group, it is also possible to use
a pure olefin and to add ammonia, NH₃. That is, a physical mixture of these substances
is used rather than a chemical compound. Such mixture produces a polymer coating with
free amino groups on the surface of the medical device as well.
[0028] Another useful functional group is the carboxyl group, -COOH. The respective chemical
agents (monomer plus functional group) are therefore preferably unsaturated carboxylic
acids, e.g. acrylic acid (H₂C=CH-COOH), butenoic acid (H₂C=CH-CH₂-COOH), pentenoic
acid (H₂C=CH-CH₂-CH₂-COOH), and so on. The general chemical formula for such unsaturated
carboxylic acids is H₂C=CH-(CH₂)
n-COOH (n=0,1,2,...).
[0029] The -OH group as such has also been found to be suited as functional group. A typical
chemical agent (monomer plus functional group) of this kind is ally alcohol, H₂C=CH-CH₂-OH.
The general group of alcohols useful for the present invention can be given by the
formula H₂C=CH-(CH₂)
n-OH, n=0,1,2,...
[0030] It should be noted that the above formula (1) does not cover all possible types of
monomeres. For example, a monomer with triple bond, i.e. a monomer with the general
structural formula
R₁ - C ≡ C - R₂ (2)
could be used in the present invention as well. An example of such a monomer with
additional functional group (in this case, an amino group) is HC≡C-CH₂-NH₂ (3-amino-1-propine);
the general notation for the class of amino compounds of this type is HC≡C-(CH₂)
n-NH₂, n=0,1,2,...
[0031] The most general definition of a monomer is a substance which is able to polymerize.
Formulae (1) and (2) are thus limited generalizations only and do not cover all possible
types of monomeres.
[0032] It will be appreciated that the examples of chemical agents, monomeres and functional
groups described above, although they have proven very useful for the present invention,
relate to preferred embodiments only, and that the skilled man may be able to identify
other chemical agents, monomeres or functional groups suited for this invention. The
above examples illustrate that there is a large variety of chemical agents, even of
basically different constitution, fulfulling the needs of the invention.
[0033] It will further be appreciated that, instead of applying a chemical agent consisting
of monomer molecules chemically combined with functional groups to the surface of
the medical device, it is also possible to apply the pure monomer and to accomplish
its desired chemical composition with a functional group in the plasma, i.e. under
electromagnetic radiation. In this case, a substance has to be added to the pure monomer
which is able to form a functional group under radiation, which then combines with
the pure monomer. The "chemical agent" referred to above is thus created
in situ as an intermediate product, which then reacts in the described manner, i.e. by forming
a functional polymer on the surface of the medical device. That is, although the process
is started with a physical mixture instead of a chemical compound, its result, and
even the second step, are the same as if a chemical composition were used.
[0034] One example of this kind has already been described above. This was the physical
mixture of a pure olefin and ammonia, which then forms a chemical compound with an
-NH₂ group under the influence of radiation. Other substances which may be physically
added to the monomer are e.g. carbon dioxide (CO₂) in case a carboxyl group is intended
to be chemically bound to the monomer as an intermediate product, or water (H₂O) in
case the intermediate product should comprise an -OH group. Other such substances
useful to create suitable functional groups are available to the skilled man.
[0035] In an alternative embodiment of the invention, the so-called plasma grafting technique
(in contrast to the plasma polymerization technique described above) is used. This
technique comprises two basic steps: In the first basic step, a chemically inert gas
(e.g. a noble gas such as argon, helium or neon) is applied to the medical device,
and the source of electromagnetic radiation is turned on. This creates or induces
charge carriers in the surface of the medical device. These charge carriers remain
present even when the source of radiation is switched off.
[0036] In the second basic step, the medical device is exposed to a chemical agent of the
same constitution as in the plasma polymerization technique (if the process is performed
in a closed chamber, the inert gas is removed by suction, and the chemical agent is
allowed to stream into the chamber). However, in this second step, the source of electromagnetic
radiation, i.e. the spark discharge, is
switched off. The charge carriers in the outer layers of the surface of the medical device however
initiate the polymerization process.
[0037] The major advantage of the plasma grafting technique is that the ends of several
polymer chains are
covalently bound to the surface of the medical device. That is, there is also a chemical bonding between
the surface of the medical device and the polymer coating, not only between the polymer
coating and the biological coating. This further reduces the probability that the
biological coating, with or without polymer coating, may detach from the surface of
the medical device.
[0038] A further advantage of the plasma grafting technique is that shorter polymer chains
are created. The monomeres do not or hardly polymerize among each other, but on the
surface of the medical device only, so that the process is more effective.
[0039] It is understood that a physical mixture of a pure monomer and a substance which
is able to form the required functional group during or just immediately prior to
the polymerization process may also be used when performing the plasma grafting technique.
However, a slight distinction to the plasma polymerization technique has to be noted
in this case. The functional monomer consisting of monomer molecules with additional
functional group is formed during the second step of the plasma grafting process
in situ, i.e. when the radiation source is switched
off. This means that a monomer and a substance have to be used which are able to combine
chemically under the influence of the charge carriers created in the first step (appliance
of inert gas and spark discharge), instead as under spark discharge as in the plasma
polymerization technique. However, most monomeres and substances used in the plasma
polymerization technique may also be used for the plasma grafting technique, and the
skilled man will be able to identify further suited substances.
[0040] In an advantageous embodiment, a further method step is added to the plasma polymerization
technique or the plasma grafting technique. This further step is performed
prior to any of the polymerization steps. It consists of exposing the medical device to a
chemically active (aggressive) gas, such as oxygen, and switching the source of radiation
on. During spark discharge impurities, e.g. dust, residues left by fingerprints etc.,
are sparked until the surface of the medical device is substantially clean from such
impurities. The additional step of cleaning the surface has the further advantage
that additional charge carriers are created in the outer surface of the medical device.
However, in contrast to the plasma grafting technique, the charge carriers created
during the purifying process recombine quite quickly as soon as the radiation source
is switched off and the purifying gas (chemically active gas) is removed. This effect
may be prevented in that the purifying gas is immediately replaced by an inert gas,
e.g. by flushing the purifying gas out with the inert gas.
[0041] One may imagine that the above process steps may be combined in any suitable manner,
dependent on the equipment and the requirements of the application. For example, the
plasma polymerization technique may be used, with or without prior purifying step.
Further, the plasma grafting technique may or may not be combined with the purifying
step. In a preferred embodiment, incorporating the plasma grafting technique with
prior purification, the inventive method comprises therefore three different states
of the process:
1. Apply chemically active gas (e.g. oxygen), switch on radiation - the surface of
the medical device is purified by sparking, and temporary charge carriers are created
in the outer surface.
2. Flush the chemically active gas out by an inert gas (e.g. argon) while the radiation
source is still operating - the temporary charge carriers created during step 1 are
thus made "quasi-permanent", i.e. become charge carriers with a considerably longer
lifetime, and further charge carriers are created.
3. Flush the inert gas out with a functional monomer (monomer with functional groups),
switch off source of radiation - the charge carriers in the outer surface of the medical device
start the polymerization. By the way, the inert gas may also rarify the functional
monomer.
[0042] As outlined above, step 3 could be replaced by flushing with a mixture of a pure
monomer and a substance, such as ammonia, so that the functional monomer is created
just prior to polymerization ("
in situ").
[0043] It is a goal of all the various techniques described above to establish a functional
polymer coating on the surface of the medical device which is able to chemically react
with the biological coating, i.e. to have the functional groups of the polymer bind
to certain molecules of the biological coating. A method of binding heparin to -NH₂
groups is e.g. described in the above-mentioned United States Patent US 4,810,784
wherein the amino groups are reacted with "fragment" heparin carrying a terminal aldehyde
group to a Schiffs base, which is then, by reduction, converted to a secondary amine
(it has to be noted that the results of this prior art technique are not always reliable
if no further measures are taken. This may be caused by the fact that functional polymeres
are directly (i.e. without polymerization) applied to the surface of a device by vaporizing
the solution in which the polymer is dissolved, as described above).
[0044] Another approach to bind the biological coating to the surface with functional polymer
is e.g. esterification. Such binding process may be useful if the biological coating
is based on phosphorylcholine (two -OH groups of the polymer coating and of the biological
coating are esterified, i.e. bind to each other whilst a H₂O group is removed). A
further possibility to bind the biological coating to the polymer coating is acid
amide formation. For the purpose of illustration, an example how a polyallylamine
as the functional polymer may bind to phosphorylcholine as biological coating is given
here:
[0045] People skilled in the art will be aware of further suitable mechanisms suited for
the specific biological coating used.
[0046] In general, the biological coating may be applied to the polymer coating according
to any prior art technique. This has particularly the advantage that, in order to
practice the present invention, not the complete coating process has to be adapted,
but only the plasma polymerization step.
[0047] As will already be apparent from the foregoing, several functional groups are useful
to fulfil the need of the present invention. What is, in general, required is a chemically
active group, i.e. a group which is responsive to substitution or rearrangement (suitable
mechanisms are e.g. amide formation, amine formation, esterification, etherification,
etc.). For example, any halogen group would be suited as a functional group, whereas
a methyl group would not be.
[0048] An important, but not strictly required, property of the present invention is that
the functional groups bound to the monomeres are
stable, even after the plasma polymerization or grafting process. For example, the -NH₂
group of the created functional polymer does not react with other chemical substances
after the plasma coating process. Therefore, it is possible to apply the biological
coating at a later point in time or even at a different location, which in turn makes
the process and the handling easier.
[0049] The invention also relates to an apparatus for performing the method according to
the present invention. In general, most of the components of the apparatus are elements
commonly used to perform plasma polymerization or plasma grafting. However, a container
has to be provided filled with a chemical agent consisting of monomer molecules chemically
combined with functional groups, said chemical agent being present at least in its
gaseous state, wherein said container is lockably connected with said chamber. The
locking means may e.g. be a valve. In this combination, the required functional monomer
may be provided to the reaction or discharge chamber. Further containers may be provided
for a chemically active gas (for the purification step) or for an inert gas (in case
plasma grafting is intended).
[0050] According to a further, preferred embodiment of the present invention, a shelf or
rack in said chamber is provided for suspending or hanging of medical devices. This
is particularly useful if intravascular blood gas sensors have to be coated, which
should not be in contact with the walls of the chamber, in order to provide a complete
coating on its whole surface.
[0051] The present invention further relates to the use of a chemical agent consisting of
monomer molecules chemically combined with functional groups, or of a monomer mixed
with a substance which, under the influence of electromagnetic radiation or of charge
carriers, forms a functional group which binds chemically to said monomer, for pretreatment
of a medical device prior to appliance of a biological coating.
[0052] The invention will now be described, by way of a non-limiting example and with reference
to the accompanying drawings, in which:
Figs. 1-3 depict the schematics of an intravascular blood gas sensor which needs to
be coated with a biological coating, wherein
- Fig. 1
- shows the basic arrangement of an intravascular blood gas measuring system,
- Fig. 2
- is a longitudinal section of a single sensor forming part of the probe,
- Fig. 3
- is a longitudinal section of the probe tip,
Figs. 4-6 depict suitable chemical agents to practice the invention,
- Fig. 7
- depicts the result of a plasma polymerization process,
- Fig. 8
- depicts the result of a plasma grafting process, and
- Fig. 9
- depicts a suitable apparatus for practising the invention.
[0053] Fig. 1 depicts a system for the invasive measurement of blood parameters, for example
of the partial carbon dioxide pressure (pCO₂) or the pH value. The light of an optical
transmitter 1 is directed into an optical fiber 2 (see arrow 2a). Preferably, this
is a glass fiber. Usually a train of light pulses is used, but this is not a strict
requirement. The light passes an optical coupler 3 and reaches tip 4 of the sensor,
said tip being intended for introduction into the artery of a patient. Tip 4 of the
sensor contains a gel into which a dye such as phenol red is immobilized. Said dye
modifies at least one optical parameter, preferably the intensity, of the light depending
on the pCO₂ (or, in other cases, the pO₂ or the pH) value of the blood. The modified
light is reflected into the same fiber and, after passing through optical coupler
3, reaches an optical receiver 5 (see arrow 5a). It is understood that optical transmitter
1 and optical receiver 5 are incorporated in a monitor or other measuring instrument.
Dashed line 6 indicates a releasable connection between the probe 7 and the monitor
8. The optical probe consists of a multiplicity of sensors and the related number
of optical fibers; preferably, it comprises 3 sensors responsive to pO₂, pCO₂ and
pH.
[0054] Operation of a single sensor will now be explained by means of Fig. 2 which shows
a longitudinal section through a pH sensor. The mechanical construction of the pH
sensor is typical for sensors of this type; the pO₂ and the pCO₂ sensor have a similar
construction.
[0055] According to Fig. 2, the pH sensor comprises a glass fiber 9 and an optical reflector
10. Optical reflector 10 is made of stainless steel. Between the optical fiber 9 and
the reflector 10, a gel 11 is located. This gel is used to immobilize a dye such as
phenol red, the optical characteristics of which varies with the blood parameter -
in this case, pH - to be measured. The surface 10a of the optical reflector 10 facing
the gel 11 is polished.
[0056] The sensor is surrounded by a semi-permeable or selective membrane 12 which is fastened
on the sensor by means of a glue 13. As Fig. 2 depicts, the glue is only introduced
at the distal end of the sensor (left side in Fig. 2) and at the very proximal end.
The selective membrane is permeable to the ions or gas molecules to be measured. In
case of the pH sensor shown in Fig. 2, the selective membrane is permeable to H⁺ ions.
[0057] Fig. 3 depicts a longitudinal section of the probe tip 14 of an optical probe comprising
three sensors, according to prior art design. A sheath 15 is closed at its outer end
(proximal end) by a metal cap 16 and connected, as shown by 17, with a tubing element
18. The connection between sheath 15 and tubing element 18 is secured by adhesive
means. Tubing element 18 ends (not shown) at a connector for connection to an appropriate
monitor.
[0058] Sheath 15 contains three sensors, two of which are shown in Fig. 3, namely a pH sensor
19 and a pCO₂ sensor 20. A third sensor, namely a pO₂ sensor, is not shown in Fig.
3 as it is hidden behind pCO₂ sensor 20.
[0059] Each of the sensors is connected with the associated monitor via an optical fiber,
as shown by optical fiber 21 (which is surrounded by an appropriate envelope 22) for
the case of pH sensor 19 in Fig. 3; likewise, reference number 23 relates to the optical
fiber of pCO₂ sensor 20, and reference number 24 to the envelope of this fiber.
[0060] The various sensors are fastened within sheath 15 by means of a silicone glue or
adhesive 25. Sheath 15 further comprises three openings, the first of which is labeled
as 26 in Fig. 3, whereas the second opening 27 is hidden behind the pCO₂ sensor 20.
The third opening is not shown in Fig. 3; it is contained in the broken-away part.
These openings ensure that, when the probe tip is introduced into a patient's artery,
the sensors are in contact with the blood thus allowing gas molecules and hydrogen
ions to reach the sensors.
[0061] PCO₂ sensor 20 further comprises a dye-containing gel 28 and an optical reflector
29. The region where dye-containing gel 28 is located is also called "diffusion zone".
Sensor 20 is, insofar as contained in sheath 15, surrounded by a semi-permeable membrane
30 which is fixed on optical fiber 23 and reflector 29 by means of a further glue
or adhesive.
[0062] In similar manner, pH sensor 19 comprises a dye-containing gel 31, a reflector 32
and a semi-permeable membrane 33.
[0063] It is understood that the probe depicted in Fig. 3 is only a typical example for
an invasive optical blood parameter probe. In other embodiments, the probe may comprise
less sensors or even more elements, such as a strain relieving wire.
[0064] As the probe is intended for insertion into a blood vessel, typically the arteria
radialis or the arteria femoralis, and therefore is in blood contact over several
hours or even days, a biological or bioactive coating is required in order to avoid
that the blood clots attach to the sensor or the surrounding catheter and thus impact
the measurement or cause thrombosis.
[0065] In a specific embodiment, the probe tip or the whole sensor is exposed to an oxygen
atmosphere in a pressure-tight chamber. The chamber may be part of a usual plasma
polymerization or plasma grafting equipment. The pressure in the chamber is then considerably
reduced to 0.7 millibar (7·10⁻⁴ bar) Thereafter, a source of radiation is turned on
which emits RF (radio frequency) waves into the chamber. In the present embodiment,
a frequency of 13.56 MHz has been used and a transmitter power of 90 mW (milliwatts);
the radiation source was turned on for a duration of 5 minutes. This first step sparks
or "burns" impurities on the surface of the probe. Further, charge carriers are generated
in the outer surface of the probe.
[0066] In a second step, argon is used to flush the oxygen out of the chamber. The radiation
transmitter is still operating, also at a power of 90 mW. The pressure in the chamber
is further reduced to 0.2 millibar (2·10⁻⁴ bar) The radiation source is operated for
5 minutes during this second step.
[0067] The purpose of this treatment with argon under spark discharge is to create further
charge carriers, and to make the charge carriers already created in the first step
"quasi-permanent".
[0068] When the second step is completed, the source of radiation is switched off. In a
third step, allylamine is fed into the chamber and flushes the argon out. The charge
carriers in the outer surface of the probe initiate the polymerization process. The
allylamine molecules polymerize on the surface of the probe (but not in the gaseous
environment); due to the charge carriers in the surface, the ends of a multiplicity
of the polymer chains attach to the surface, such that the generated polymer coating
is in "chemical" contact with the surface (which in turn inhibits removal of the plasma
coating). The outer ends of the polymer chains carry free and stable amino groups
(NH₂).
[0069] The probe may now be removed from the chamber and coated with a biological coating
in basically known manner.
[0070] The process described above is the plasma grafting process. In the case of plasma
polymerization, the second step (argon flushing) is not performed, and a monomer is
fed into the chamber for 20 minutes at a pressure of 0.3 millibar (3·10⁻⁴ bar).
[0071] Fig. 4 depicts a selection of suitable carboxylic compounds (monomer with carboxyl
group) suitable as chemical agents in the third step. The general formula is given
in Fig. 4(a), wherein (CH₂)
n denotes an arbitrary number of CH₂ groups, n=0 or an integer. Figs. 4(b) to 4(c)
illustrate some agents out of this group; e.g., Fig. 4(b) is acrylic acid, Fig. 4(c)
is butenoic acid and Fig. 4(d) is pentenoic acid.
[0072] Likewise, Fig. 5(a) shows the general formula for agents with an amino group. Specific
examples of this group of substances are: Allylamine (Fig. 5(b)) and 4-amino-1-butene
(Fig. 5(c)).
[0073] Fig. 6(a) is the general formula of suitable alcohols (compounds with an - OH group);
Fig. 6(b) depicts a typical example of this group, allyl alcohol.
[0074] The difference between the plasma polymerization technique and the plasma grafting
technique is shown in Fig. 7 and 8. Fig. 7 shows a plasma polymer 34 with free amino
(-NH₂) groups (at every 2
nd carbon atom in the polymer chain) on the surface 35 of an intravascular probe obtained
with the plasma polymerization technique. In contrast, the result of the plasma grafting
technique is depicted in Fig. 8. The ends of the plasma grafted chains 36 adhere to
the surface 37, as depicted by reference number 38. This is a covalent bonding which
provides better contact between polymer and surface and reduces the probability of
detachment of the polymer. Further, the polymer chains in the environment of Fig.
8 are generally shorter.
[0075] The basics of an apparatus for performing the inventive method is shown in Fig. 9.
A pressure-tight, electrically shielded chamber 39 contains a shelf or rack 40 for
pinning up of intravascular probes. The front opening 41 may be closed by a suitable
door (not shown).
[0076] A pump 42 is used to obtain the required low pressure. It is connected via tube 43
to back wall 44 of chamber 39. The source of radiation is depicted as 45.
[0077] Three openings 46, 47 and 48 are provided as inlets for oxygen, argon and allylamine
(or polyacrylic acid), respectively. These openings are connected via tubes 49, 50
and 51 to respective containers 52, 53 and 54 holding these gases, or volatile liquids.
1. Method of pretreating the surface of a medical device for appliance of a biological
coating, characterized by the steps of:
(1.1) exposing said medical device to a chemical agent consisting of monomer molecules
chemically combined with functional groups, or of a monomer mixed with a substance
which, under the influence of electromagnetic radiation, forms a functional group
which binds chemically to said monomer, said chemical agent being present at least
in its gaseous state,
(1.2) irradiating electromagnetic waves, in particular of the radio frequency range,
into said chemical agent and/or onto the surface of said medical device until the
molecules of said chemical agent constitute a functional polymer on the surface of
said medical device.
2. Method for applying a biological coating to the surface of a medical device intended
for blood contact, characterized by the steps of:
(2.1) exposing said medical device to a chemical agent consisting of monomer molecules
chemically combined with functional groups, or of a monomer mixed with a substance
which, under the influence of electromagnetic radiation, forms a functional group
which binds chemically to said monomer, said chemical agent being present at least
in its gaseous state,
(2.2) irradiating electromagnetic waves, in particular in the radio frequency range,
into said chemical agent and/or onto the surface of said medical device until the
molecules of said chemical agent constitute a functional polymer on the surface of
said medical device,
(2.3) applying said biological coating to the surface of said medical device.
3. Method of pretreating the surface of a medical device for appliance of a biological
coating, characterized by the steps of:
(3.1) exposing said medical device to an inert gas,
(3.2) irradiating electromagnetic waves, in particular of the radio frequency range,
into said inert gas and/or onto the surface of said medical device,
(3.3) exposing said medical device to a chemical agent consisting of monomer molecules
chemically combined with functional groups, or of a monomer mixed with a substance
which, under the influence of charge carriers created during step (3.2), forms a functional
group which binds chemically to said monomer, said chemical agent being present at
least in its gaseous state, until the molecules of said chemical agent constitute
a functional polymer on the surface of said medical device.
4. Method for applying a biological coating to the surface of a medical device intended
for blood contact, characterized by the steps of:
(4.1) exposing said medical device to an inert gas,
(4.2) irradiating electromagnetic waves, in particular of the radio frequency range,
into said inert gas and/or onto the surface of said medical device,
(4.3) exposing said medical device to a chemical agent consisting of monomer molecules
chemically combined with functional groups, or of a monomer mixed with a substance
which, under the influence of charge carriers created during step (4.2), forms a functional
group which binds chemically to said monomer, said chemical agent being present at
least in its gaseous state, until the molecules of said chemical agent constitute
a functional polymer on the surface of said medical device,
(4.4) applying said biological coating to the surface of said medical device.
5. Method according to any of the preceding claims, characterized in that said chemical
agent is contained in a closed chamber (39) which also contains said medical device.
6. Method according to claim 5, characterized in that said chamber (39) is pressure-tight
and that a pressure below atmospheric pressure is applied to said chamber.
7. Method according to claim 6, characterized in that the pressure in said chamber (39)
is approximately a vacuum, in particular in the range of 10⁻⁵ bar to 10⁻² bar and
more specifically in the range of 10⁻⁴ bar to 10⁻³ bar.
8. Method according to any of the preceding claims, characterized in that said monomer
comprises molecules consisting of at least two carbon atoms combined by double bond.
9. Method according to any of the preceding claims, characterized in that said functional
group in said molecules of said chemical agent is an amino group.
10. Method according to claim 9, characterized in that said chemical agent is allylamine,
4-amino-1-butene or any other olefin with additional amino group, or a combination
of olefin and ammonium hydroxyde.
11. Method according to any of claims 1 to 8, characterized in that said functional group
in said molecules of said chemical agent is a carboxyl group.
12. Method according to claim 11, characterized in that said chemical agent is one selected
of the group of carboxylic acids, in particular acrylic acid, butenoic acid, or pentenoic
acid.
13. Method according to any of claims 1 to 8, characterized in that said functional group
in said molecules of said chemical agent is an OH group.
14. Method according to claim 13, characterized in that said chemical agent is ally alcohol.
15. Method according to any of the preceding claims, characterized by the additional steps
of
(15.1) exposing said medical device to a chemically active gas, in particular oxygen,
(15.2) irradiating electromagnetic waves into said chemically active gas and/or onto
the surface of said medical device until the surface of said medical device is substantially
clean of impurities,
wherein said steps are performed prior to exposing said medical device to said chemical
agent.
16. Method according to any of the preceding claims, characterized by the step of applying
said biological coating to the polymerized surface of said medical device by means
of esterification, acid amide formation, acid amine formation, or etherification.
17. Method according to any of the preceding claims, characterized in that said medical
device is an intravascular blood gas sensor.
18. Apparatus for pretreatment of the surface of a medical device for appliance of a biological
coating, said apparatus comprising a pressure-tight chamber (39) with a releasable
lock for insertion of said medical device and with a source (45) of electromagnetic
radiation, preferably in the radio frequency range, for performing plasma polymerization,
characterized by a container (54) filled with a chemical agent consisting of monomer
molecules chemically combined with functional groups, or consisting of a monomer mixed
with a substance which, under the influence of electromagnetic radiation or of charge
carriers, forms a functional group which binds chemically to said monomer, said chemical
agent being present at least in its gaseous state, said container (54) being lockably
connected with said chamber (39).
19. Apparatus according to claim 18, characterized by a second container (52;53) filled
with a chemically active gas or an inert gas and being lockably connected with said
chamber.
20. Apparatus according to claim 18 or 19, characterized by a shelf or rack (40) in said
chamber (39) suited for suspending or hanging of said medical devices, in particular
intravascular blood gas sensors.
21. Use of a chemical agent consisting of monomer molecules chemically combined with functional
groups, or of a monomer mixed with a substance which, under the influence of electromagnetic
radiation or of charge carriers, forms a functional group which binds chemically to
said monomer, for pretreatment of a medical device prior to appliance of a biological
coating.